BTZ black hole with KdV-type boundary conditions:
Thermodynamics revisited
Cristian Erices,a,b Miguel Riquelme,c,d,e Pablo Rodrıguez,c,f,g
aDepartment of Physics, National Technical University of Athens, Zografou Campus GR 157 73,
Athens, Greece.bUniversidad Catolica del Maule, Av. San Miguel 3605, Talca, Chile.cCentro de Estudios Cientıficos (CECs), Av. Arturo Prat 514, Valdivia, Chile.dFacultad de Ingenierıa y Tecnologıa, Universidad San Sebastian, General Lagos 1163, Valdivia
5110693, Chile.eFundacion Cultura Cientıfica, Valdivia 5112119, Chile.fDepartamento de Fısica, Universidad de Concepcion, Casilla 160-C, Concepcion, Chile.gInstituto de Ciencias Fısicas y Matematicas, Universidad Austral de Chile, Casilla 567, Valdivia,
Chile
E-mail: [email protected], [email protected], [email protected]
Abstract: The thermodynamic properties of the Banados-Teitelboim-Zanelli (BTZ) black
hole endowed with Korteweg-de Vries (KdV)-type boundary conditions are considered.
This familiy of boundary conditions for General Relativity on AdS3 is labeled by a non-
negative integer n, and gives rise to a dual theory which possesses anisotropic Lifshitz
scaling invariance with dynamical exponent z = 2n + 1. We show that from the scale
invariance of the action for stationary and circularly symmetric spacetimes, an anisotropic
version of the Smarr relation arises, and we prove that it is totally consistent with the
previously reported anisotropic Cardy formula. The set of KdV-type boundary condi-
tions defines an unconventional thermodynamic ensemble, which leads to a generalized
description of the thermal stability of the system. Finally, we show that at the self-dual
temperature Ts = 12π (1z )
zz+1 , there is a Hawking-Page phase transition between the BTZ
black hole and thermal AdS3 spacetime.
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Contents
1 Introduction 1
2 General Relativity on AdS3 and the KdV-type boundary conditions 3
2.1 The BTZ black hole with KdV-type boundary conditions 4
3 The anisotropic Smarr formula as a radial conservation law 5
3.1 Conserved charge at infinity 6
3.2 Conserved charge at the event horizon 7
4 The anisotropic Cardy formula 8
5 Thermodynamic stability and phase transitions 10
6 Outlook and ending remarks 13
1 Introduction
In the pursuit of a better understanding of quantum gravity, in the past two decades, a
lot of interest has been put into the so called Gauge/Gravity correspondence, whose most
celebrated example is the AdS/CFT duality [1, 2]. In this context, AdS3/CFT2 corre-
spondence has played an important role. One of the first main results was the renowned
article from Brown and Henneaux [3], where they showed that the asymptotic symmetries
of General Relativity in three dimensions with negative cosmological constant correspond
to the conformal algebra in two dimensions with a classical central extension. This result
naturally suggest that a quantum theory of gravity in three dimensions could be described
by a CFT at the boundary. Based on this result, Strominger [4] proved that the entropy of
the Banados-Teitelboim-Zanelli (BTZ) black hole [5, 6] can be recovered by a microscopic
counting of states by means of the Cardy formula [7]. This simple example gave rise to an
active field of research regarding the thermodynamic properties of lower dimensional black
holes and how they could be holographically related to a dual field theory that describes
the much sought after quantum theory of gravity.
In the static case, the thermodynamic stability of the BTZ black hole has qualitatively
a different behaviour than its higher dimensional counterparts. In fact, in four dimensions,
the canonical ensemble for the Schwarzschild solution is not well-defined [8]. This difficulty
is avoided by the presence of the negative cosmological constant [9], but nevertheless, since
the specific heat of Schwarzschild-AdS4 black hole presents discontinuities, the system can
not reach thermal equilibrium with a thermal bath at any temperature. In the case of
three dimensions, none of the above arguments hold [10–12], since the specific heat of the
– 1 –
BTZ is a monotonically increasing positive function of the temperature, as the case of any
Chern-Simons black hole in odd dimensions [13–15].
Several efforts have been made to generalize the Gauge/Gravity proposal for non AdS
asymptotics (see e.g. [16–19]). In this scenario, a lot of attention has been placed on gravity
dual theories with anisotropic scaling properties, which are found in the context of non-
relativistic condense matter physics (see references in [20]). The main work on this subject
has been done along the lines of Lifshitz holography, where the gravity counterparts are
given by asymptotically Lifshitz geometries (see e.g. [21] and references therein). However,
this class of spacetimes are not free of controversies. In particular, the Lifshitz spacetime
(which would play the role of ground state in the thermodynamic description) suffer from
divergent tidal forces. Additionally, asymptotically Lifshitz black holes are not vacuum
solutions to General Relativity, and it is mandatory to include extra matter fields as in the
case of Proca fields [21], p-form gauge fields [22, 23], to name a couple of examples.
In the present work, we will adopt a different approach to this holographic realization,
where the anisotropic scaling properties of the boundary field theory instead emerge from a
very special choice of boundary conditions for General Relativity on AdS3. This new set of
boundary conditions is labeled by a nonnegative integer n, and is related with the Korteweg-
de Vries (KdV) hierarchy of integrable systems [24]1. Allowing that at the asymptotic region
the Lagrange multipliers could depend on the global charges, it was shown that the reduced
phase space of Einstein field equations is given precisely by two copies of the n-th member
of the KdV hierarchy. It is worth to emphasize that, although these boundary conditions
describe asymptotically locally AdS3 spacetimes, the associated dual field theory possesses
an anisotropic scaling of Lifshitz type,
t→ λzt , φ→ λφ , (1.1)
where the dynamical exponent is given by z = 2n + 1. In the context of black hole
thermodynamics, KdV-type boundary conditions define an unconventional thermodynamic
ensemble, which leads to a generalized thermodynamic description of the BTZ black hole.
Remarkably, this thermodynamic description shows very similar features with the ones
found in the study of Lifshitz black holes [27–31], and has a deep relationship with the
work of Hardy and Ramanujan on the counting of partitions of an integer into z-th powers
[32]. In this work, we will focus on the main characteristics that this thermodynamic
ensemble implies, and its differences with the standard analysis.
The paper is organized as follows. In Section 2 we provide a brief review of KdV-
type boundary conditions in the context of Chern-Simons description of General Relativity
with negative cosmological constant in three dimensions. In Section 3 it is shown that an
anisotropic Smarr formula emerges from the radially conserved charge associated with the
scale invariance of the reduced Einstein-Hilbert action endowed with KdV-type boundary
conditions. Section 4, is devoted to the anisotropic Cardy formula and the relation with
its Smarr counterpart. Finally, the thermal stability of BTZ black hole with KdV-type
1Other examples of this relationship between 2D integrable systems and gravity in 2+1, have been also
made for the cases of “flat” and “soft hairy” boundary conditions in [25] and [26], respectively.
– 2 –
boundary conditions is deeply analyzed in Section 5. We conclude with some comments in
Section 6.
2 General Relativity on AdS3 and the KdV-type boundary conditions
General Relativity with negative cosmological constant in three dimensional spacetimes can
be formulated as the difference of two Chern-Simons actions for gauge fields A±, evaluated
on two independent copies of the sl(2,R) algebra [33, 34],
IEH = ICS [A+]− ICS [A−] , (2.1)
The above action corresponds precisely to General Relativity on AdS3 only if both Chern-
Simons levels are given by k = `/4G, where ` is the AdS radius and G the Newton constant.
In order to describe the asymptotic form of the fields, it is convenient to do the analysis
using auxiliary fields a±, which are defined by a precise gauge transformation on A± [35],
A± = b−1±(a± + d
)b± , (2.2)
with b± = e±log(r/`)L±0 2. So that, the radial component of a± vanishes, while the remain
ones only depend on time and the angular coordinate. Proceeding as in [36, 37], the
non-vanishing components of the auxiliary fields are given by
a±φ = L± −1
4L±L∓ , a±t = ±µ±L± − ∂φµ±L0 ±
1
2
(∂2φµ± −
1
2µ±L±
)L∓ , (2.3)
where L±(t, φ) stand for the dynamical fields, and µ±(t, φ) correspond to the values of the
Lagrange multipliers at infinity. In the asymptotic region, the field equations reduce to
∂tL± = ±D±µ± , D± := (∂φL±) + 2L±∂φ − 2∂3φ . (2.4)
It is worth highlighting that the boundary conditions are fully specified once a precise
form of the Lagrange multipliers at infinity is provided. In the standard approach of
Brown and Henneaux [3], the Lagrange multipliers are set as µ± = 1. Going one step
further, one can generalize this analysis by choosing arbitrary functions of the coordinates,
µ± = µ±(t, φ), which, in order to have a well-defined action principle, are held fixed at
the boundary (δµ± = 0) [36, 37]. However, even beyond that, one can still guarantees the
integrability of the boundary term in the action, if one allow that the Lagrange multipliers
may depend on the dynamical fields and their spatial derivatives, giving rise to a complete
new set of boundary conditions. Here, we will focus on the family of KdV-type boundary
conditions, introduced in [24], which are labeled by a non negative integer n. In this context,
the Lagrange multipliers are chosen to be given by the n-th Gelfand-Dikii polynomial
evaluated on L± and can be obtained by the functional derivative with respect to L± of
the n-th Hamiltonian of the KdV hierarchy, i.e.,
µ(n)± [L±] =
δH(n)±
δL±, (2.5)
2The representation that we use is the same as in [36].
– 3 –
where the following recursion relation is satisfied
∂φµ(n+1)± =
n+ 1
2n+ 1D±µ(n)± . (2.6)
Thus, for the case n = 0, one recovers the Brown-Henneaux boundary conditions (µ(0)± = 1),
and in consequence, according to (2.4), the dynamical fields are chiral. In the case n = 1,
the Lagrange multipliers are given by µ(1)± = L±, and then the field equations reduce to
two copies of the KdV equation, while for the remaining cases (n > 1) the field equations
are given by the corresponding n-th member of the KdV hierarchy.
As a consequence of the reduction of Einstein field equations to the KdV hierarchy3,
the “boundary gravitons” (global gravitational excitations) possess an anisotropic scaling
of Lifshitz type
t→ λzt , φ→ λφ , L± → λ−2L± , (2.7)
where the dynamical exponent z is related to the KdV label n by z = 2n + 1. It must
be remarked that, although the solutions of Einstein field equations are locally AdS3, they
inherit an anisotropic scaling from the choice of KdV-type boundary conditions. For this
reason, the thermodynamic properties of black holes will also carry a z-dependence.
According to the canonical approach [40], the variation of the generators of the asymp-
totic symmetries are readily found to be given by δQ = δQ+[ε+]− δQ−[ε−], where
δQ±[ε±] = − `
32πG
ˆdφ ε±δL± . (2.8)
In particular, when the gauge parameters are related with the asymptotic Killing vec-
tors ∂φ and ∂t, one can integrate (2.8) directly. Indeed, the angular momentum is given
by
Q [∂φ] =`
32πG
ˆdφ (L+ − L−) , (2.9)
while for time translations,
δQ [∂t] =`
32πG
ˆdφ (µ+δL+ + µ−δL−) , (2.10)
which by virtue of (2.5), the energy integrate as
Q [∂t] =`
32πG
(H
(k)+ +H
(k)−
). (2.11)
2.1 The BTZ black hole with KdV-type boundary conditions
For each allowed choice of n (or equivalently z), the spectrum of solutions is quite different.
Nonetheless, BTZ black hole [5, 6] fits within every choice of boundary conditions in (2.5).
3As shown in [38], by performing the Hamiltonian reduction of KdV-type boundary conditions, the
equations (2.4) actually corresponds to the conservation law of the energy-momentum tensor of the corre-
sponding theory at the boundary. For the particular case n = 0, the field equations are equivalent to the
aforementioned conservation law. See also [39], for a recent related result, in the case of “near horizon”
boundary conditions.
– 4 –
Indeed, this class of configurations is described by constant L±, which trivially solves (2.4)
for all possible values of n. In this case, according to the normalization choice in (2.6), it
is possible to show that the Lagrange multipliers generically acquire a remarkably simple
form, µ(n)± = Ln±N±, where N± is assumed to be fixed without variation at the boundary
(δN± = 0). Note that µ(0)± = N±, so in that special case, the Lagrange multipliers at
infinity are held constants but given by arbitrary values, and the standard Brown-Henneaux
analysis [3] is recovered by setting N± = 1. In this scenario, along the lines of [37], the
Lagrange multipliers are allowed to depend on the dynamical fields, which amounts to a
different fixing of the “chemical potentials” at the boundary, implying that we are dealing
with the same black hole configuration but in a different thermodynamic ensemble (see
e.g., [41]). In what follows, we will use the dynamical exponent z, instead of the KdV-label
n, so by using z = 2n+ 1, we can rewrite the KdV-type Lagrange multipliers as4,
µ± = Lz−12± N± . (2.12)
The energies of the left and right movers also takes a simple form for a generic choice of
n, namely E± = `32πGH
(n)± = `
16G1
n+1Ln+1± . Therefore, in terms of the dynamical exponent
we can rewrite them as
E± =`
8G
1
z + 1L
z+12± . (2.13)
From the gravitational perspective, according to (2.11), the energy of the BTZ black hole
is determined by E = E+ + E− .
In the next section we will show that an anisotropic version of Smarr formula naturally
emerges as the consequence of the scale invariance of the reduced Einstein-Hilbert action,
as long as we consider the KdV-type boundary conditions.
3 The anisotropic Smarr formula as a radial conservation law
In [46], the authors showed that the reduced Einstein-Hilbert action coupled to a scalar
field in AdS3 spacetimes is invariant under a set of scale transformations which leads to
a radial conservation law by using the Noether theorem. When this conserved quantity is
evaluated in a particular solution of the theory, namely, a black hole solution, one obtains
a Smarr relation [47]. This method has been successfully applied to several cases in the
literature [48–55] for different theories. By following this procedure, we show that it is
possible as well, to obtain a generalization of the Smarr formula for the BTZ black hole
endowed with KdV-type boundary conditions. As a consequence, the entropy as a bilinear
form of the global charges of the black hole, manifestly depends on the dynamical exponent.
In the metric formulation, the Einstein-Hilbert action has the following form
IEH =
ˆd3x√−g[
1
2κ(R− 2Λ)
], (3.1)
where κ = 8πG, and the cosmological constant is related to the AdS radius by Λ = −`−2.4In the context of AdS/CFT holography, the relationship between the chemical potentials and conserved
charges is known as “multi-trace deformations” of the dual theory [42–45].
– 5 –
By considering stationary and circularly symmetric spacetimes described by the fol-
lowing line element
ds2 = −N (r)2F (r)2 dt2 +dr2
F (r)2+ r2
(dφ+N φ (r) dt
)2, (3.2)
the reduced action principle in the canonical form is given by
I = −2π (t2 − t1)ˆdr(NH+N φHφ
)+B , (3.3)
where the boundary term B must be added in order to have a well-defined variational
principle. The surface deformation generators H, Hφ acquire the following form
H = − r
κ`2+ 4κr(πrφ)2 +
(F2)′
2κ, (3.4)
Hφ = −2(r2πrφ)′ , (3.5)
where N and N φ stand for their corresponding Lagrange multipliers. The only nonvanish-
ing component of the momenta πij is explicitly given by
πrφ = −(N φ)′r
4κN, (3.6)
where prime denotes derivative with respect to r.
The above reduced action principle turns out to be invariant under the following set
of scale transformations
r = ξr , N = ξ−2N , N φ = ξ−2N φ , F2 = ξ2F2 , (3.7)
where ξ is a positive constant. By applying the Noether theorem, we obtain a radially
conserved charge associated with the aforementioned symmetries,
C(r) =1
4G
[−NF2 +
rN(F2)′
2−r3(N φ)′N φ
N
], (3.8)
which means that C ′ = 0 on-shell.
We will find a Smarr formula by exploiting the fact that this conserved charge must
satisfy C(∞) = C(r+), where r+ is the event horizon of the BTZ black hole solution with
KdV-type boundary conditions.
3.1 Conserved charge at infinity
For the class of configurations considered here, the metric functions in “Schwarzschild”
coordinates are given by
N (r) =`
2(µ+ + µ−) ,
N φ(r) =1
2(µ+ − µ−) +
`2
8r2(L+ − L−) (µ+ + µ−) , (3.9)
F2(r) =r2
`2− 1
2(L+ + L−) +
`2
16r2(L+ − L−)2 .
– 6 –
where µ± corresponds to the arbitrary values of the Lagrange multipliers at infinity, leading
to a simple expression for the radially conserved charge at infinity,
C(∞) =`
8G(µ+L+ + µ−L−) . (3.10)
Thus in the case of KdV-type boundary conditions (2.12), can be written as
C(∞) =`
8G
(N+L
z+12
+ +N−Lz+12−
), (3.11)
which in terms of the left and right energies (2.13), reads
C(∞) = (z + 1)N+E+ + (z + 1)N−E− . (3.12)
3.2 Conserved charge at the event horizon
To evaluate the radial charge at the event horizon we must ensure that the Euclidean
configuration is smooth around this point. The inner and outer horizons r± in these
coordinates, are determined by F2(r±) = 0, where r± = `2
(√L+ ±
√L−). In consequence,
it is clear that the regularity requirement in this gauge translates into,
N (r+)F2(r+)′ = 4π , N φ(r+) = 0 , (3.13)
which implies that the Euclidean metric becomes regular for µ± = 2π√L±
. Considering the
regularity conditions (3.13) and the metric functions F2, N and N φ, the value of the radial
charge at the event horizon is
C(r+) =πr+2G
= S , (3.14)
which corresponds to the entropy of the BTZ black hole.
Now, by making use of the equality C(r+) = C(∞), the anisotropic Smarr formula is
obtained5,
S = (z + 1)N+E+ + (z + 1)N−E− . (3.15)
Identifying the Lagrange multipliers as the inverse of left and right temperatures T± =
N−1± , the above expression acquires the following form,
S = (z + 1)E+
T++ (z + 1)
E−T−
. (3.16)
Turning off the angular momentum, this expression reduces to6
E =1
(z + 1)TS , (3.17)
5Resembling expressions for the entropy as a bilinear combination of the global charges times the chemical
potentials have been previously found for three dimensional black holes and cosmological configurations in
the context of higher spin gravity [36, 56, 57], hypergravity [58, 59] and extended supergravity [60]. The
factor in front of each term corresponds to the conformal weight (spin) of the corresponding generator.6The left and right temperatures are related with the Hawking temperature through T =
2T+T−
(T++T−), so
in the absence of rotation T+ = T− = T .
– 7 –
which is in agreement with Smarr formula for Lifshitz black holes in three dimensions
found in the literature (see e.g. [29, 30]). It is worth to point out that since the BTZ black
hole with generic boundary conditions is asymptotically AdS3, the contribution due to the
rotation naturally appears in the anisotropic Smarr formula (3.15), despite the fact that,
as far as the knowledge of the present authors, there is no a rotating Lifshitz black hole in
three dimensions. It is also worth mentioning that in the limit z → 0, (3.15) fits with the
corresponding Smarr relation of soft hairy horizons in three spacetimes dimensions [61].
It is worth to remark that the scaling (3.7) is equivalent to the scaling of the Lifshitz
type introduced in (2.7). By redefining the scale factor as λ→ ξ−1 in (3.7), we obtain
t→ ξ−zt , r → ξr , φ→ ξ−1φ , L± → ξ2L± . (3.18)
Then, in the case of KdV-type boundary conditions (2.12), we can see that the Lagrange
multipliers at infinity scales as µ± = ξz−1µ±, therefore from (3.9), we can deduce that Nand N φ scales accordingly. Now, since the reduced Hamiltonian action does not depend
on t and φ, before integrate them, we can absorb its scalings on the Lagrange multipliers,
and in consequence, they must scale as N = ξ−2N and N φ = ξ−2N φ, which is in full
agreement with (3.7).
In the following chapter, we will show that by considering a two dimensional field theory
defined on the torus, it is possible to recover the anisotropic Smarr formula by means of
an anisotropic version of the standard S-modular invariance of the partition function.
4 The anisotropic Cardy formula
On this section, we will tackle the thermodynamical description of the BTZ black hole
from an holographic perspective. The partition function of the 2D dual field theory is
made up by the contribution of two non interacting left and right systems, each one with
a corresponding temperature given by T+ = β−1and T− = β−1− . The modular parameter
of the torus τ , where the theory is defined, is related to the left and right periods of the
thermal cycle, β+ and β−, by
τ =iβ+2π
, τ = − iβ−2π
. (4.1)
As argued in [24] and [62], the partition function of the dual field theory at the bound-
ary is invariant under the anisotropic S-duality transformation, given by
Z[β±; z] = Z[(2π)1+1z β− 1
z± ; z−1] , (4.2)
and, by assuming the existence of a gap in the energy spectrum it is possible to write the
partition function as the contribution of two pieces
Z(β+, β−) = e−I(β+,β−) + e−I0(β+,β−) , (4.3)
such that, at low temperatures, the contribution of the ground state I0 dominates the
partition function, so it can be approximated by
Z(β+, β−) ≈ exp(−β+E0
+ − β−E0−), (4.4)
– 8 –
and by virtue of the anisotropic S-duality, at high temperature regime the partition function
acquires the following form
Z(β+, β−) ≈ exp
−(2π)1+1z
β1z+
E0+[z−1]− (2π)1+
1z
β1z−
E0−[z−1]
. (4.5)
It is well known that by taking the inverse Laplace transform of the partition function
(4.5) we can obtain the asymptotic growth of the density of states
ρ(E+, E−) =1
(2πi)2
ˆ +i∞
−i∞dβ+dβ−e
β+E++β−E−Z(β+, β−)
≈ 1
(2πi)2
ˆdβ+dβ−e
f++f− ,
(4.6)
where the function f± is defined as
f±(β±, E±, E0±) := −(2π)1+
1z
β1z±
E0±[z−1] + β±E± . (4.7)
We can evaluate this expression using the saddle-point approximation for fixed energies in
the limit of E± |E0±|. Indeed, there is a critical point β±(E±, E
0±),
β± = 2π
(−E0±[z−1]
zE±
) z1+z
. (4.8)
Then, the entropy of the system
S = log ρ ≈ f+(β+, E+, E0+) + f−(β−, E−, E
0−) , (4.9)
will be given by two copies of the anisotropic Cardy formula7 [24], [62],
S = 2π (z + 1)
[(|E0
+[z−1]|z
)zE+
] 1z+1
+ 2π (z + 1)
[(|E0−[z−1]|z
)zE−
] 1z+1
. (4.10)
Remarkably, if instead, we consider the ground state energies in terms of the inverse
temperatures and the left and right energies,
∣∣E0±[z−1]
∣∣ = zE±[z]
(β±2π
)1+ 1z
, (4.11)
in (4.9), we found that the entropy reduces to
S = (z + 1)E+β+ + (z + 1)E−β− ,
7As explained in [24], for odd values of n = (z−1)/2, Euclidean BTZ with KdV-type boundary conditions
is diffeomorphic to thermal AdS3, but with reversed orientation, and in consequence, there is a opposite
sign between Euclidean and Lorentzian left and right energies of the ground state. As it will be shown in
the next section, this leads to a local thermodynamic instability of the system for odd values of n. So, it is
mandatory to adopt E0±[z−1
]→ −
∣∣E0±[z−1
]∣∣, in the Lorentzian ground state energies of the anisotropic
Cardy formula.
– 9 –
which exactly matches with the anisotropic Smarr formula previously obtained by consid-
ering the scale symmetry of the Einstein-Hilbert reduced action (3.16). This relationship
between Cardy and Smarr formulas has been previously suggested in the literature [29].
Interestingly enough, the link between both expressions is the anisotropic version of the
Stefan-Boltzmann law, which is nothing else than the relation between energy and temper-
ature given by the critical point (4.11).
From equation (4.10), it is clear that the entropy written as a function of left and right
energies scales as
S (λE+, λE−) = λσS (E+, E−) , (4.12)
where
σ =1
(z + 1). (4.13)
Hence, it is reassuring to prove that, by simply applying the Euler theorem for homogeneous
functions, gives
S (E+, E−) = (z + 1) (E+β+ + E−β−) , (4.14)
in the same way than the original derivation found in [47].
The following section is devoted to the local and global thermal stability of the BTZ
black hole endowed with KdV-type boundary conditions.
5 Thermodynamic stability and phase transitions
We analyze the thermodynamic stability at fixed chemical potentials. Local stability condi-
tion can be determined by demanding a negative defined Hessian matrix of the free energy
of the system (see e.g. [63]). Nonetheless, in this ensemble it can equivalently be performed
by the analysis of the left and right specific heats with fixed chemical potential. From the
anisotropic Stefan-Boltzmann law
E± [z] =1
z|E0±[z−1]| (2π)1+
1z T
1+ 1z
± , (5.1)
one finds that left and right specific heats are given by
C± [z] =∂E±∂T±
=z + 1
z2|E0±[z−1]|(2π)1+
1z T
1z± . (5.2)
We see that, for all possible values of z, the specific heats are continuous monotonically
increasing functions of T±, and always positive8, which means that the system is at least
locally stable. It is important to remark that, as mentioned at the end of the last section,
if we had not warned on the correct sign of the ground state energies for odd n, the sign of
the specific heats would have depended on z, and in consequence, for odd values of n the
black hole would be thermodynamically unstable.
8Strictly speaking, specific heats C± are always positive provided that T± > 0. In terms of the tem-
perature and angular velocity of the black hole, the above is equivalent to the non-extremality condition;
0 < T , −1 < Ω < 1 . Since in the present paper we are not dealing with the extremal case, we will consider
that this condition is always fulfilled.
– 10 –
Since the specific heats are finite and positive regardless of the value of z, the BTZ
black hole with generic KdV-type boundary conditions can always reach local thermal
equilibrium with the heat bath at any temperature.
Once local stability is assured, it makes sense to ask about the global stability of the
system. Following the seminal paper of Hawking and Page [9], we use the free energies at
fixed values of the chemical potentials of the two phases present in the spectrum (BTZ and
thermal AdS3), in order to realize which one is thermodynamically preferred.
In the semiclassical approximation, the on-shell Euclidean action is proportional to
the free energy of the system. Taking into account the contributions of the left and right
movers, the action acquires the following form
I = N+E+ +N−E− − S . (5.3)
Assuming a non-degenerate ground state with zero entropy and whose left and right energies
are equal and negative defined, E± → −∣∣E0 [z]
∣∣, we see that the value of the action of the
ground state is given by
I0 = −|E0 [z] |(
1
T++
1
T−
). (5.4)
On the other hand, considering in (5.3) a system whose entropy is given by the formula
(3.15), we obtain that
I = −z (N+E+ +N−E−) , (5.5)
hence, using the formulae for the energies in (5.1), the action then reads
I = −|E0[z−1]| (2π)
z+1z
(T
1z+ + T
1z−
). (5.6)
Therefore, it is straightforward to see that, regardless of the value of z, the partition
function Z = eI+I0 , will be dominated by (5.4) at low temperatures, and by (5.6) at the
high temperatures regime. It can also be shown that, consistently, we are able to found the
same ground state action by making use of the anisotropic S-duality transformation (4.2)
on (5.6).
In what follows, we will focus on the simplest case where the whole system is in
equilibrium at a fixed temperature T± = T . Then, the free energy of the system at high
and low temperatures will respectively given by
F = −2|E0[z−1]| (2π)1+
1z T 1+ 1
z , F0 = −2|E0 [z] | , (5.7)
and comparing them, we can obtain the self-dual temperature, at where both free energies
coincide,
Ts [z] =1
2π
∣∣∣∣ E0 [z]
E0 [z−1]
∣∣∣∣z
z+1
, (5.8)
which manifestly depend on the dynamical exponent. An interesting remark is worth to
be mentioned. The fact that the self-dual temperature Ts depends on the specific choice
of boundary conditions, is because the S-duality transformation involves an inversion of
– 11 –
0.05 0.10 0.15T
-1.0
-0.5
0.0
F
z=1z=3z=9
F0F
T TsssT
F
T
Figure 1. Free energies of the BTZ black hole and thermal AdS3 spacetime with KdV-type
boundary conditions associated to the dynamical exponents z = 1 ; 3 ; 9.
the dynamical exponent between the high and low temperature regimes, namely, z → z−1.
This is a highly non trivial detail in the calculation. If one does not take it into account,
the self-dual temperature would be the same for all values of z.
On the other hand, computing the free energies of the BTZ black hole and thermal
AdS3 spacetime, we obtain
FBTZ = − `
4G
z
z + 1(2πT )
z+1z , FAdS = − `
4G
1
z + 1, (5.9)
and then, the self-dual temperature for which the two phases are equally likely is
Ts [z] =1
2π
(1
z
) zz+1
. (5.10)
which exactly matches with (5.8), if one identifies the ground state energy of the field
theory with the one of the AdS3 spacetime with KdV-type boundary conditions, i.e., E0 →12EAdS [z] = − `
8G1z+1 .
As it shown in Figure 1, for an arbitrary temperature below the self-dual temperature
(T < Ts), the thermal AdS3 phase has less free energy than the BTZ, and therefore the
former one is the most probable configuration, while if T > Ts, the black hole phase
dominates the partition function and hence is the preferred one. Note that for higher values
of z, the self-dual temperature becomes lower. The latter point entails to a remarkable
result. In the case of Brown-Henneaux boundary conditions (z = 1), one can deduce that
in order for the black hole reach the equilibrium with a thermal bath at the self-dual point
Ts, the event horizon must be of the size of the AdS3 radius, i.e., r+ = `. Nonetheless, for
a generic choice of z, the horizon size has to be
rs+ [z] = `
(1
z
) 1z+1
. (5.11)
– 12 –
This means that the size of the black hole at the self-dual temperature decreases for higher
values of z. In the same way, at Ts, the energy of the BTZ, EBTZ = E+ + E−, endowed
with generic KdV-type boundary conditions, acquires the following form
Es [z] =`
4G
1
z (z + 1), (5.12)
and when compared to the AdS3 spacetime energy,
∆E = EBTZ − EAdS =`
4G
1
z, (5.13)
we can observe that at the self-dual temperature there is an endothermic process, where
the system absorbs energy from the surround thermal bath at a lower rate for higher values
of z.
From these last points we can conclude that the global stability of the system is cer-
tainly sensitive to which KdV-type boundary condition is chosen, since the free energy of
the possible phases of the system are explicitly z-dependent. Moreover, the temperature at
which both phases have equal free energy, the size of the black hole horizon and the internal
energy of the system at that temperature, decrease for higher values of z, giving rise to a
qualitatively different behavior of the thermodynamic stability of the system, compared to
the standard analysis defined by z = 1.
6 Outlook and ending remarks
The purpose of this work is twofold. On one hand, we have shown that the anisotropic
Smarr relation for the BTZ black hole endowed with KdV-type boundary conditions can
be obtained by following three different approaches. First, by means of the Noether the-
orem, we obtained a radial conserved quantity, which once evaluated in the BTZ solution
naturally leads to an expression for the entropy as a z-dependent bilinear combination of
the conserved charges times the chemical potentials at infinity. Secondly, we prove that the
same formula can be obtained through the anisotropic S-duality of the partition function
of a dual 2D field theory, and we show its close relationship with the corresponding Cardy-
like formula. Finally, by considering the scaling properties of the entropy as a function of
the charges, it was possible to recover the aforementioned Smarr relation from the Euler
theorem for homogeneous functions.
The second aim of this work is devoted to the thermodynamical stability of the system.
We have shown that, as it is expected for a black hole solution in a Chern-Simons theory,
the specific heat of the BTZ black hole is a positive, monotonically increasing function of
the temperature, independently of the choice of KdV-type boundary condition. In contrast,
it was shown that the global stability of the system is sensitive to the specific choice of
boundary conditions. There is Hawking-Page phase transition at an specific z-dependent
self-dual temperature Ts, for which, at temperatures below this point, the preferred phase
is the AdS3 spacetime, and for higher temperatures, the BTZ black hole is the more stable
phase. This self-dual temperature decreases for higher values of z, as does the size of the
– 13 –
black hole horizon and the energy that the system absorbs from the environment in order
for the transition occurs.
Remarkably, the anisotropic scaling properties which are commonly realized in the
context of Lifshitz holography, now take place in the General Relativity scenario. This is
because the KdV-type boundary conditions induce these kind of scaling properties in the
dual theory allowing to study Lifshitz holography in a simple setup. This fact leads to
an interesting consequence, as it can be seen that rotation terms naturally appears in the
anisotropic Smarr formula, despite that there is no a rotating Lifshitz black hole in three
dimensions.
Along this work it has been assumed that the cosmological constant is a fixed constant
without variation. However, is it possible to follow another point of view. If the energy
of the black hole is no longer the mass but the thermodynamical enthalpy, the Smarr
formula and a extended first law, can be found by considering a variable cosmological
constant which can be related with pressure and volume terms (see e.g. [64–67]). In the
literature, there is a standard mechanism described in [68], which explain how to promote
the cosmological constant to a canonical variable. Nonetheless, at least in three dimensions,
there is a superselection rule that forbids this possibility [69], in consequence, it cannot be
rescaled.
Acknowledgments
We would like to thank Oscar Fuentealba, Cristian Martınez, Alfredo Perez, David Tempo
and Jorge Zanelli, for helpful comments and discussions. We are indebted to Ricardo
Troncoso for especially valuable comments and encouragement. C.E. thanks CONICYT
through Becas Chile programme for financial support. The work of P.R. was partially
funded by PhD CONICYT grant Nº 21161262 and Fondecyt grant Nº 1171162. M.R. is
supported by Fondecyt grant Nº 3170707. Centro de Estudios Cientıficos (CECs) is funded
by the Chilean Government through the Centers of Excellence Base Financing Program of
CONICYT.
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